JP2019066206A - Surface elastic wave sensor and measuring system - Google Patents

Abstract

To provide a surface elastic wave sensor with which, when a surface elastic wave sensor is inserted into a measuring device, it is possible to identify the type of inspection of the inserted surface elastic wave sensor.SOLUTION: This surface elastic wave sensor excites a surface elastic wave on a substrate and measures the properties of a detection object placed on or contacted with a detection part on the substrate according to a property change of the surface elastic wave. The surface elastic wave sensor includes a surface elastic wave element for identification that excites a surface elastic wave for identification, separately from the surface elastic wave for detection, for identifying the measurement object of the surface elastic wave sensor, and uses the propagation characteristic of the surface elastic wave as identification information.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a surface acoustic wave sensor and measurement system having surface acoustic wave components.

  In general, the surface acoustic wave device includes a piezoelectric substrate, and an input electrode and an output electrode which are composed of comb-like electrode fingers provided on the piezoelectric substrate. As a sensor using a surface acoustic wave element, a surface using shear surface acoustic wave (SH-SAW: hereinafter, simply, surface elasticity) which is displaced in a direction perpendicular to the propagation direction among surface acoustic waves. An elastic wave sensor for performing detection of various substances and measurement of physical property values and the like using an elastic wave element has been studied (see Patent Document 1).

The surface acoustic wave sensor provided with the above-mentioned surface acoustic wave element is considered as a biosensor which inspects kinds, such as a flu test kit, for example. Since the sample directly touches the reaction detection portion, it is basically used on the assumption that it is disposable. For this reason, the measurement system is generally divided into a surface acoustic wave sensor and a measurement device. The measuring device has a general-purpose configuration that can correspond to a surface acoustic wave sensor that performs any type of inspection, and the input / output terminal of the surface acoustic wave sensor is inserted into the input terminal. The characteristic data of the sample detected by the surface acoustic wave sensor is input.
Then, the detection device analyzes the supplied characteristic data to obtain an inspection result, and notifies the inspection result from an output device such as a display device.

Patent No. 3481298

However, although it is indicated by printing or a seal on the package or box of the surface acoustic wave sensor whether the surface acoustic wave sensor corresponds to the inspection, the surface elasticity is once taken out of the package or the box. It becomes difficult to distinguish the type of inspection that the wave sensor supports.
For this reason, when performing the first type of inspection, if the surface acoustic wave sensor of the second type of inspection different from the surface acoustic wave sensor of the first type of inspection is inserted in the detection device, the first Type of examination is not performed, and the necessary examination results can not be obtained.

  The present invention has been made in consideration of the above problems, and when the surface acoustic wave sensor is inserted into the measuring device, the surface elasticity which can identify the type of the inserted surface acoustic wave sensor inspection It is an object to provide a wave sensor and measurement system.

The surface acoustic wave sensor according to the present invention excites a surface acoustic wave on a substrate, and measures the physical properties of the object to be detected which is placed on or in contact with the detection unit on the substrate by changing the characteristics of the surface acoustic wave. A wave sensor, which is a surface acoustic wave for detection, separately from the detection surface acoustic wave, for identification of a measurement object of the surface elastic wave sensor, the identification surface acoustic wave is excited to propagate the surface acoustic wave It is characterized by having a surface acoustic wave element for identification which makes a characteristic the identification information.
In the surface acoustic wave sensor of the present invention, the identification surface acoustic wave element has an identification reflection electrode that reflects the identification surface acoustic wave of a predetermined identification frequency, and the reflection characteristic from the identification reflection electrode is a surface It is characterized in that it is identification information of an elastic wave sensor.

  According to the present invention, it is possible to provide a surface acoustic wave sensor and a measurement system capable of identifying the type of inspection of the surface acoustic wave sensor when inserted into the measurement device.

It is a figure which shows an example of the measurement system using the surface acoustic wave sensor which mounts ID information by 1st Embodiment. The schematic in the top view which looked at the surface acoustic wave sensor of 1st Embodiment from the upper surface is shown. It is a figure which shows the structural example of ID reflective electrode 1032. FIG. It is a figure which shows the structural example of the detection apparatus 2 by 1st Embodiment. It is a figure which shows the bit table corresponding to arrangement | positioning of ID reflective electrode of FIG. It is the schematic in the upper surface view which looked at the surface acoustic wave sensor of 2nd Embodiment from the upper surface. It is a figure which shows the structural example of each of ID reflective electrode 1032 and ID reflective electrode 1033. FIG. It is a figure which shows the bit table corresponding to arrangement | positioning of ID reflective electrode of FIG. It is a figure which shows the other bit table corresponding to arrangement | positioning of ID reflective electrode of FIG. It is a figure which shows the structural example of ID reflective electrode 1032. FIG. It is a figure which shows the bit table corresponding to the reflective intensity of the ID reflective electrode of FIG. It is a figure which shows the structural example of ID reflective electrode 1032 and ID reflective electrode 1033. FIG. It is a figure which shows the bit table corresponding to arrangement | positioning of ID reflective electrode of FIG. It is a figure which shows the bit table corresponding to arrangement | positioning of ID reflective electrode of FIG.

  The present invention is a surface acoustic wave sensor provided with a surface acoustic wave sensor element, and in particular, identifies the type of inspection of the surface acoustic wave sensor separately from the surface acoustic wave element for detection which detects the characteristics of the inspection object A surface acoustic wave element for identification showing ID (Identification) information (hereinafter also referred to as identification information) is provided, and the frequency of the surface acoustic wave, the delay time of the surface acoustic wave or the signal of the surface acoustic wave in the surface acoustic wave element for identification Each of the strengths is used as ID information indicating the type of test of each surface acoustic wave sensor.

First Embodiment
Hereinafter, a surface acoustic wave sensor equipped with identification information according to the first embodiment will be described with reference to the drawings. FIG. 1 is a view showing an example of a measurement system using a surface acoustic wave sensor equipped with identification information according to the first embodiment. The measurement system includes a surface acoustic wave sensor 1, a detection device 2, and an evaluation server 3. The surface acoustic wave sensor 1 measures the type of solution based on a biosensor that measures the characteristics of a sample (test object), a gas sensor that measures the type of gas, and the electrical characteristics (such as conductivity and relative permittivity) of the solution. Solution detection sensor or the like. That is, the surface acoustic wave sensor 1 excites the surface acoustic wave on the substrate, and changes the characteristics of the surface acoustic wave, the physical property of the inspection object being the detected object placed or in contact with the detection unit on the substrate. taking measurement. By inserting the terminal 1a of the surface acoustic wave sensor 1 into the terminal 2a of the detection device 2, the detection device 2 acquires identification information from the surface elastic wave sensor 1, and identifies the type of inspection to be performed by the surface elastic wave sensor 1. Do. Therefore, the detection device 2 has, for example, a type table or a bit table (described later) for identifying identification information of the surface acoustic wave sensor 1 and a type of inspection of the surface acoustic wave sensor 1. The detection device 2 and the evaluation server 3 are connected by wire or wirelessly, and if they are wired, they are connected by using, for example, a USB (Universal Serial Bus) cable.
The evaluation server 3 performs control of measurement on the detection device 2, display of measurement results, accumulation of measurement results, and the like. Further, the evaluation server 3 displays (outputs) the identification result of the surface acoustic wave sensor supplied from the detection device 2 and the measurement result of the surface acoustic wave sensor 1.
However, the roles of the detection device 2 and the evaluation server 3 can be made to have the function of the evaluation server 3 in the detection device 2 regardless of the form described above. For example, display of measurement results and accumulation of measurement results Also good.

FIG. 2 is a schematic view of the surface acoustic wave sensor according to the first embodiment of the present invention as viewed from above, viewed from above. The surface acoustic wave sensor shown in FIG. 2 uses a reflective surface acoustic wave sensor element (surface acoustic wave element). The substrate 101 is not particularly limited in material, but is made of a material capable of propagating surface acoustic waves, for example, a piezoelectric substrate such as quartz crystal or LiTaO ₃ (Lithium Tantalate) single crystal. On the surface 101S of the substrate 101, each of the surface acoustic wave element 102 for detection and the surface acoustic wave element 103 for identification, which is of a reflective type, is formed. The surface acoustic wave element 102 for detection has each of an input / output electrode 1021, a reflective electrode 1022, and a reaction area thin film 1023. The surface acoustic wave element 103 for identification has each of the ID input / output electrode 1031 and the ID reflection electrode 1032, but does not have a reaction area thin film. Each of the input / output electrode 1021, the reflective electrode 1022, the input / output electrode 1031, and the ID reflective electrode 1032 is a comb-shaped electrode composed of electrodes of a pair of comb-like electrode fingers opposed to each other. Is formed by patterning. The reaction area thin film 1023 is a metal thin film, for example, gold is deposited to form a thin film, and an antibody or an antigen for detecting an object to be detected is immobilized on the surface of the gold thin film. The reaction area thin film 1023 becomes a detection area (an area to be a detection surface of the sensor). A sample is introduced into this detection area. An electric signal is supplied from the detection device 2 to the input / output electrodes 1021 and 1031 to generate an electric field between the electrode fingers, and a surface acoustic wave is excited by the piezoelectric effect to propagate on the surface 101S of the substrate 101 which is a piezoelectric substrate. Do.

The reaction area thin film 1023 is disposed on the surface 101 S of the substrate 101 on the propagation path of the surface acoustic wave between the input / output electrode 1021 and the reflective electrode 1022. The surface acoustic wave propagates in the direction H indicated by the arrow in FIG. 2 (the direction from the input / output electrode 1021 to the reflective electrode 1022).
The reflective electrode 1022 is a reflector that reflects the surface acoustic wave (detection surface acoustic wave) of a predetermined detection frequency used for measurement and transmits surface acoustic waves other than the detection frequency.
The ID reflective electrode 1032 reflects surface acoustic waves (identification surface acoustic waves) of the identification frequency which is the same as or different from the detection frequency and which is a predetermined frequency used to acquire identification information, and surface elasticity other than the identification frequency It is a reflector that has the property of transmitting waves.

  FIG. 3 is a view showing a configuration example of the ID reflective electrode 1032. In FIG. 3, a plan view of the ID reflective electrode 1032 viewed from the top surface of the surface acoustic wave sensor 1 is shown. The comb-teeth-shaped electrode fingers 1032A and 1032B are formed such that their respective comb-teeth are alternately arranged and face each other on the surface 101S (FIG. 2). Each of the comb-like electrode fingers 1032A and 1032B is electrically connected by a pattern 1032L. In the pattern 1032L, an area 1032T in which trimming is performed is provided. When the area 1032 T is fused, the surface acoustic wave of the identification frequency is reflected at such a level that it can be detected. On the other hand, when each of the comb-like electrode fingers 1032A and 1032B is electrically connected, the reflection intensity is lowered to a level at which the reflected surface acoustic wave can not be detected. That is, a threshold for detecting the presence or absence of reflection is provided, and if the intensity of the reflected surface acoustic wave is equal to or higher than this threshold, it can be determined that there is reflection of the surface acoustic wave and no reflection if it is less than the threshold.

Further, in the present embodiment, as a modification, in addition to forming the trimming area on the substrate 101 on which the surface acoustic wave element is formed as described above, the surface acoustic wave sensor 1 (PC substrate) mounting the surface acoustic wave element A trimming area may be formed on the top. Further, as another modification, identification information may be provided to the surface acoustic wave sensor 1 depending on whether or not an ID reflective electrode is formed. That is, the identification information may be provided to the surface acoustic wave sensor 1 depending on whether or not the ID reflective electrode 1032 is formed. In this case, the formation of the pattern 1032L is irrelevant. Further, as a modification, the external terminals of the comb-like electrode fingers 1032A and 1032B are provided on the PC substrate of the surface acoustic wave sensor 1, and the identification information is set depending on whether or not they are connected by a conductor such as a lead wire. good.
Each of the above-described modifications may be used as a modification of another embodiment described later, as in the present embodiment.

FIG. 4 is a view showing a configuration example of the detection device 2 according to the first embodiment of the present invention. The detection device 2 includes each of an input / output control unit 21, a signal control unit 22, a determination unit 23, and a storage unit 24. The detection device 2 is, for example, a device configured by a microcomputer and a memory (storage unit 24), and an application program for performing inspection processing corresponding to the type of inspection item of the surface acoustic wave sensor 1 is installed. Then, in the detection device 2, each function of the input / output control unit 21, the signal control unit 22 and the determination unit 23 is executed as a unit that performs an inspection process by a software program. Further, in the storage unit 24, a program of the application is installed, and identification information for identifying the surface acoustic wave sensor 1 to be referred to by this program and described later is stored. Also in the other embodiments described later, as in the present embodiment, the program of the application is installed in the storage unit, and identification information for identifying the surface acoustic wave sensor 1 to be referred to by this program is stored. It is done.
In the present embodiment, the case where the identification information is the presence / absence information indicating the presence / absence of reflection will be described as an example.

  The input / output control unit 21 transmits / receives data to / from the surface acoustic wave sensor 1 when the surface acoustic wave sensor 1 is inserted into the detection device 2. The signal control unit 22 transmits an electrical signal of the detection frequency and the identification frequency to the surface acoustic wave sensor 1 via the input / output control unit 21, and the surface reflected by the reflective electrode from the surface acoustic wave sensor 1. An electrical signal corresponding to the elastic wave is obtained. When an electrical signal corresponding to the reflected surface acoustic wave is obtained, the signal control unit 22 outputs a numerical value indicating the frequency to the determination unit 23 as presence / absence information indicating that there is reflection. Here, the signal control unit 22 detects whether the electrical signal output to the surface acoustic wave sensor 1 is reflected or not within a predetermined delay time after the output of the electrical signal.

  In addition, when the reflection of the electric signal can not be detected in the delay time within the predetermined range, the signal control unit 22 determines that the ID reflective electrode does not exist, and the presence / absence information indicating that there is no reflection from the ID reflective electrode Are output to the determination unit 23. If the numerical value indicating the frequency in the obtained presence / absence information is a predetermined identification frequency, the determination unit 23 refers to the presence / absence information of reflection in the storage unit 24. In the present embodiment, the surface acoustic wave sensor 1 of two types of inspection is identified in order to determine whether to arrange one ID reflective electrode 1032 as identification information of the type of inspection.

When the presence / absence information obtained from the signal control unit matches the presence / absence information (identification information of the type of inspection) of the storage unit 24, the determination unit 23 determines that the type of inspection of the surface acoustic wave sensor 1 is the type of inspection of the application program It is determined that it matches. Then, the determination unit 23 causes the detection device 2 to execute an inspection process on the surface acoustic wave sensor 1 according to the type of inspection of the application program.
On the other hand, when the presence / absence information obtained from the signal control unit does not match the presence / absence information of the storage unit 24, the determination unit 23 determines that the type of inspection of the surface acoustic wave sensor 1 is different from the type of inspection of the application program. To detect. Then, the determination unit 23 does not perform the inspection process on the inserted surface acoustic wave sensor 1 on the detection device 2 (stops the inspection process), and the surface elastic wave sensor 1 is erroneously used. Is notified to the inspector in charge via the evaluation server 3.

As described above, according to the present embodiment, by forming the surface acoustic wave element for identification 103 in a channel different from the surface acoustic wave element for detection 102, the detection operation of the inspection object in the reaction area thin film 1023 is affected. Identification information can be provided to the surface acoustic wave sensor without being provided.
Further, in FIG. 2, the surface acoustic wave element 103 for identification in the surface acoustic wave sensor 1 is formed of one surface acoustic wave sensor element, that is, one channel.
However, in the case of a surface acoustic wave sensor of a plurality of channels in which surface acoustic wave sensor elements are arranged in parallel, the ID reflective electrode described above is disposed for each channel, thereby making it possible to obtain It can have an amount of information identifying the type of examination.

Further, as a modification of the present embodiment, the ID reflective electrodes of the identification information are not provided in all the channels, and the ID reflective electrodes are provided in a predetermined number of channels satisfying the number of types of inspection identified by the surface acoustic wave sensor 1. It is good also as composition provided. That is, the number of channels necessary for the number of types of inspections may be selected from a plurality of channels, and the ID reflective electrode may be disposed on the surface acoustic wave element of the selected channel.
Furthermore, in a plurality of channels, an ID reflection electrode of identification information may be provided in the surface acoustic wave element having the reaction region thin film 1023, and any of the channels may be used exclusively for identification. In this case, in the channel dedicated for identification, only the ID reflective electrode may be formed, and a plurality of ID reflective electrodes (the identification frequencies of the ID reflective electrodes are different) may be formed in order to increase the number of identification.
Each of the above-described modifications may be used as a modification of another embodiment described later, as in the present embodiment.

  Also, as another configuration of the first embodiment, the presence or absence of the identification surface acoustic wave is not directly used as identification information, but the presence or absence of the identification surface acoustic wave is once converted into a bit value, and this bit value A configuration in which the identification information is used may be used. That is, when the presence / absence of reflection of the detected identification surface acoustic wave is supplied, the determination unit 23 refers to the bit table and reads out the identification information corresponding to the presence / absence of the reflection of the detected identification surface acoustic wave. In the bit table, the presence / absence of detection of the identified surface acoustic wave and the bit value corresponding to the presence / absence of the identified surface acoustic wave are stored in association with each other. The bit table is provided in the storage unit 24.

FIG. 5 is a diagram showing a bit table corresponding to the arrangement of the ID reflective electrode of FIG. In this bit table, for example, the bit value is “1” when there is reflection of the identification surface acoustic wave, and the bit value is “0” when there is no reflection of the identification surface acoustic wave.
Here, if the bit value indicating the presence or absence of the identified surface acoustic wave matches the bit value of the identification information of the bit table, the determination unit 23 determines that the type of inspection of the surface acoustic wave sensor 1 is the type of inspection of the application program. Detect a match. On the other hand, when the determination unit 23 determines that the bit value indicating the presence or absence of the identified surface acoustic wave does not match the bit value of the identification information of the bit table, the type of inspection of the surface acoustic wave sensor 1 is one with the type of inspection of the application program. Detect that you do not do. As described above, according to another configuration example of the present embodiment, two types of surface acoustic wave sensors can be identified by 1-bit identification information.

Second Embodiment
Next, a surface acoustic wave sensor equipped with identification information according to the second embodiment will be described. FIG. 6 is a schematic view in a top view of the surface acoustic wave sensor according to the second embodiment as viewed from above. About the same composition as FIG. 2, the same numerals are attached and explanation is omitted. The surface acoustic wave element 103 for identification has each of the input / output electrode 1031 and the ID reflective electrodes 1032 and 1033, and does not have a reaction area thin film as in the first embodiment. The ID reflective electrode 1033 reflects a surface acoustic wave of an identification frequency f2 different from the identification frequency f1 of the ID reflective electrode 1032.

Here, in the input / output electrode 1031, the distance between the electrode fingers of the comb-shaped electrode is set corresponding to the inspection frequency, converts the electric signal of the identification frequency f1 into a surface acoustic wave of the identification frequency f1, and outputs the electric signal of the identification frequency f2 Are converted to surface acoustic waves of the identification frequency f2. Here, with regard to the identification frequency f2, the efficiency of conversion from the electrical signal to the surface acoustic wave may be low, and it may not be possible to obtain a surface acoustic wave of a predetermined intensity. For this reason, in the present embodiment, some electrode fingers are thinned from the electrodes designed to correspond to the identification frequency f1, and thinning electrodes (so-called, thinning is performed to weight the frequency characteristics) thinning weighting electrodes Get). The obtained thinning electrode is used as an input / output electrode 1031. When thinning out the electrode fingers, the frequency characteristics of the input / output electrode 1031 are adjusted so that the signal level of the identification frequency f2 and the signal level of the identification frequency f1 become large.
That is, in the frequency characteristics of the normal regular comb-like electrode, the attenuation of the signal level becomes larger corresponding to the function of Sin (x) / (x) as it gets farther from the center frequency. However, as in the present embodiment, it is possible to adjust the frequency characteristics with respect to the attenuation of the signal level by using the thinning electrode in which the electrode finger is thinned. By using this configuration of the thinning electrode, it is possible to design the input / output electrode 1031 in which the attenuation at a specific frequency apart from the center frequency is relatively reduced and the signal level is increased. As described above, it is effective to set relatively small attenuation frequencies to the identification frequency f1 and the identification frequency f2 at the input / output electrode 1031.

  In the second embodiment, when the signal control unit 22 identifies the type of inspection of the surface acoustic wave sensor 1, the identification frequency (f 1) of the surface acoustic wave sensor 1 is detected via the input / output control unit 21. , F2). Then, an electrical signal corresponding to the surface acoustic wave reflected by the ID reflective electrode 1032 or 1033 is obtained from the surface acoustic wave sensor 1. When outputting the electric signal of the identification frequency f1 and the electric signal of the identification frequency f2, the signal control unit 22 outputs the electric signal in time series at a predetermined interval. Further, the signal control unit 22 outputs the frequency and the delay time to the determination unit 23 as the presence or absence information of whether or not the electrical signal corresponding to the reflected surface acoustic wave is obtained. In the detection of the presence or absence of the reflection of the surface acoustic wave, it is determined whether or not an electrical signal corresponding to the surface acoustic wave reflected from the ID reflection electrode 1032 or 1033 is detected in a delay time within a predetermined time range. It takes place in When the frequency of the obtained electric signal is the identification frequency (f1, f2), the determination unit 23 uses a combination of whether or not the identification frequency (f1, f2) is reflected as identification information.

  FIG. 7 is a view showing a configuration example of each of the ID reflective electrodes 1032 and 1033. In FIG. 7, a plan view of each of the ID reflective electrodes 1032 and 1033 as viewed from the top surface of the surface acoustic wave sensor 1 is shown. Each of the ID reflective electrodes 1032 and 1033 is the same as that shown in FIG. In the present embodiment, the presence or absence of the reflection of the identification surface acoustic wave depending on whether or not each of the plurality of ID reflection electrodes 1032 is disposed is used as the identification information. For this reason, it is possible to identify the surface acoustic wave sensors 1 of the number of inspection types corresponding to the number of the ID reflective electrodes 1032 arranged.

  That is, when two types of identification frequencies f1 and f2 are used as the identification frequency, identification of the surface acoustic wave sensor 1 of 4 types of different inspection types is performed by the following four combinations according to the identification frequency and the presence or absence of reflection. It can be carried out. For example, when the surface acoustic wave of both identification frequencies f1 and f2 returns (combination A), the surface acoustic wave of identification frequency f1 returns and the surface acoustic wave of identification frequency f2 does not return (four combinations) ( Combination B), when the surface acoustic wave of the identification frequency f1 does not return and the surface acoustic wave of the identification frequency f2 returns (combination C), when the surface acoustic waves of both the identification frequencies f1 and f2 do not return (combination D) It is.

  When the frequency of the obtained electric signal is the identification frequency, the determination unit 23 refers to a combination of presence / absence of reflection of the identification frequency of the storage unit 24. Then, the determination unit 23 determines whether the combination of the presence / absence of reflection of each of the identification frequencies f1 and f2 obtained from the signal control unit 22 matches the combination of the identification frequency of the storage unit 24. If the combination of the identification frequency matches the combination of the identification frequency of the storage unit 24, the determination unit 23 determines that the type of inspection of the surface acoustic wave sensor 1 matches the type of inspection of the application program and does not match the type of inspection. Detect different from the type.

  As described above, according to the present embodiment, depending on the type of inspection of the surface acoustic wave sensor 1, whether or not the ID reflective electrode corresponding to a plurality of different identification frequencies is disposed, The identification information of the type of inspection can be easily set by the combination of the presence or absence of reflection of the identified surface acoustic wave for each identification frequency.

  In addition, as another configuration of the second embodiment, a configuration may be used in which a combination of presence / absence of reflection of identification surface acoustic waves of each identification frequency is temporarily converted into a bit value and this bit value is used as identification information . That is, when a combination of presence / absence of reflection of the identified surface acoustic wave of each of the detected identification frequencies is obtained, the determination unit 23 refers to the bit table of the storage unit 24 and reflects the identified surface acoustic wave of the identification frequency. The identification information corresponding to the presence or absence may be read out.

  FIG. 8 is a diagram showing a bit table corresponding to the arrangement of the ID reflective electrode of FIG. When the ID reflective electrode 1032 has a characteristic of reflecting a surface acoustic wave of the identification frequency f1, when an electrical signal of the identification frequency f1 is input to the input / output electrode 1031, the reflection returns to the input / output electrode 1031 within the delay time. When the ID reflective electrode 1033 is designed to reflect a surface acoustic wave of the identification frequency f 2, when an electrical signal of the identification frequency f 2 is input to the input / output electrode 1031, the reflection returns to the input / output electrode 1031 within the delay time.

  As shown in FIG. 8, in the bit table in another configuration example of the second embodiment, the first bit is set to “1” when the reflection of the surface acoustic wave of the identification frequency f1 returns within a predetermined delay time. On the other hand, if it does not return within the predetermined delay time, the first bit is set to "0". When the surface acoustic wave of the identification frequency f2 returns, the second bit is set to "1". On the other hand, when the surface acoustic wave does not return, the second bit is set to "0". Thereby, four types of surface acoustic wave sensors can be identified by 2-bit identification information. Although the identification frequency is described as two types of f1 and f2, it may be set as a number of types corresponding to the number of surface acoustic wave sensors to be identified.

When the frequency obtained from the signal control unit 22 is a preset identification frequency, the determination unit 23 refers to the bit table of the storage unit 24 for the bit value corresponding to the combination of the storage unit 24.
If the determination unit 23 converts the presence or absence of the identification surface acoustic wave into a bit value as a result of matching with the bit value of the identification information of the storage unit 24, the type of inspection of the surface acoustic wave sensor 1 is the type of inspection of the application program If it does not match, it detects that the type of examination is different.

Third Embodiment
The surface acoustic wave sensor in which identification information is set according to the third embodiment will be described below with reference to the drawings. The surface acoustic wave sensor according to the third embodiment has the same configuration as that shown in FIG. 6, but the propagation distance of the surface acoustic wave from the input / output electrode 1031 to the ID reflective electrodes 1032 and 1033 in the direction H Are controlled to control the delay time of the identification frequencies f1 and f2. Therefore, the reflection of the identification surface acoustic wave of the identification frequency f1 from the ID reflective electrode 1032 is detected at one of the delay times t1 and t2. The reflection of the identification surface acoustic wave of the identification frequency f2 reflected from the ID reflection electrode 1033 is similarly detected.

  In the case of the third embodiment, the signal control unit 22 transmits an electrical signal of the detection frequency and the identification frequency (f1, f2) to the surface acoustic wave sensor 1 via the input / output control unit 21. Then, the determination unit 23 outputs the frequency and the delay time as information indicating whether or not an electrical signal corresponding to the reflected surface acoustic wave is obtained. The signal control unit 22 detects the presence or absence of reflection of the electrical signal of the identification frequency and the respective delay times. In the present embodiment, identification information is a combination of the identification frequency of the identification frequencies f1 and f2, the delay time of reflection (t1, t2), and the presence or absence of reflection of the identification surface acoustic wave. .

That is, in the case of using two types of identification frequencies f1 and f2, in addition to the identification frequency and the presence or absence of the reflection of the identification surface acoustic wave, the following seven pieces of A combination can be made to identify the surface acoustic wave sensor 1 of seven different inspection types. In the seven combinations, when reflections of surface acoustic waves at both identification frequencies f1 and f2 return at delay times t1 and t2 respectively (combination E), reflection of surface acoustic waves at identification frequencies f1 and f2 has delay time t2 , When returning at t1 (combination F), when the reflection of the surface acoustic wave of the identification frequency f1 returns at the delay time t1 and the reflection of the surface acoustic wave of the identification frequency f2 does not return (combination G), the surface elasticity of the identification frequency f1 When wave reflection returns at delay time t2 and surface acoustic wave reflection at identification frequency f2 does not return (combination H), reflection of surface elastic wave at identification frequency f2 returns at delay time t1, and surface acoustic wave at identification frequency f1 If the reflection of the surface acoustic wave of the identification frequency f2 returns at the delay time t2 and the reflection of the surface acoustic wave of the identification frequency f1 does not return (combination J), the identification frequency Reflection of the surface acoustic wave of both 1 and f2 is a case does not return (combination K).
The determination unit 23 determines whether the combination of the presence or absence of reflection of each of the identification frequencies f1 and f2 supplied from the signal control unit 22 and the delay time of the reflection matches the identification information of the storage unit 24 or not. Then, it is determined whether the types of inspections of the surface acoustic wave sensor 1 and the application program match.

  As described above, according to the present embodiment, identification information for identifying the type of inspection of each of the surface acoustic wave sensors 1 can be easily set by a combination of presence / absence of reflection for each identification frequency and a delay time.

  Further, as another configuration of the third embodiment, a configuration may be used in which the combination of the presence or absence of reflection of the identification surface acoustic wave and the delay time of each identification frequency is temporarily converted into a bit value. That is, when the combination of the presence / absence of reflection of the identification surface acoustic wave of each identification frequency and the delay time is supplied, the determination unit 23 refers to the bit table of the storage unit 24 and identifies the identification surface elasticity of each identification frequency. The identification information corresponding to the combination of the presence or absence of the wave reflection and the delay time may be read out and determined.

  FIG. 9 is a diagram showing another bit table corresponding to the arrangement of the ID reflective electrode of FIG. The ID reflective electrode 1032 that reflects the identification frequency f1 is disposed at one of the delay time t1 and the delay time t2. When the ID reflective electrode 1032 is disposed at the position of the delay time t 1, the surface acoustic wave of the identification frequency f 1 returns to the input / output electrode 1031 after the delay time t 1 of the reflected surface acoustic wave. When the ID reflective electrode 1032 is disposed at the position of the delay time t 2, the surface acoustic wave of the identification frequency f 1 returns to the input / output electrode 103 1 after the delay time t 2 of the reflected surface acoustic wave. Further, the ID reflection electrode 1033 reflecting the identification frequency f2 is also disposed at any position of the delay time t1 and the delay time t2, and the operation in reflection of the surface acoustic wave is the same as the identification frequency f1 described above.

  As shown in FIG. 9, in the bit table in the third embodiment, when the surface acoustic wave of the identification frequency f1 returns at the delay time t1, the first bit is set to “1”, while when it does not return, The bit value of the first bit is set to "0". Also, if the reflection of the surface acoustic wave of the identification frequency f1 returns at the delay time t2 within the predetermined time, the second bit is set to "1", while the reflection does not return within the predetermined time, 2 The bit is set to "0". Similarly, if the reflection of the surface acoustic wave at the identification frequency f2 returns at a delay time t1 within a predetermined time, the third bit is set to "1" while the reflection does not return within a predetermined time, The third bit is set to "0". When the reflection of the surface acoustic wave of the identification frequency f2 returns at the delay time t2 within a predetermined time, the fourth bit is set to "1", while within a prescribed time (a time sufficiently longer than the delay time). If it does not return to, the fourth bit is set to "0". Thereby, as shown in FIG. 9, in the present embodiment, seven types of surface acoustic wave sensors can be identified by 4-bit identification information. This is because the ID reflective electrodes 1032 and 1033 can not be arranged at the same position, as can be seen from FIG.

Fourth Embodiment
The surface acoustic wave sensor of the fourth embodiment has the same configuration as that shown in FIG. Further, the identification was based on the presence / absence of reflection of the surface acoustic wave of the identification frequency f1 of the first embodiment, but in the fourth embodiment, the ID reflection electrode 1032 of the surface acoustic wave of the identification frequency f1 reflects In the present embodiment, for example, the surface acoustic wave to be incident, the reflection intensity to be 80% of the incident intensity, or a plurality of stages, for example, in the present embodiment Arbitrary settings are divided into eight levels, and the surface acoustic waves to be reflected are classified into eight levels, and used as identification information for identifying the eight types of surface acoustic wave sensors 1. Here, the impedance at the identification frequency f1 of the ID reflective electrode 1032 is adjusted so that the reflection intensity of the ID reflective electrode 1032 is one of eight levels for each surface acoustic wave sensor. The ID reflective electrode 1032 is connected to a capacitor or an inductor or a pattern of an impedance circuit including a capacitor and an inductor. Then, by controlling the cut portion of the pattern of the impedance circuit, the impedance of the ID reflective electrode 1032 can be arbitrarily replaced to adjust the reflection intensity. The cutting of this pattern is performed, for example, by laser trimming.

  FIG. 10 is a view showing a configuration example of the ID reflective electrode 1032. In FIG. 10, a plan view of the ID reflective electrode 1032 as viewed from the upper surface of the surface acoustic wave sensor 1 is shown. The patterns 1032 LA and 1032 LB are connected to the comb-like electrode fingers 1032 A and 1032 B, respectively. Impedance circuits 1032I1, 1032I2 and 1032I3 are connected in parallel between the patterns 1032LA and 1032LB. The impedance circuit 1032I1 is connected to the pattern 1032LB via the region 1032T1, the impedance circuit 1032I2 is connected to the pattern 1032LB via the region 1032T2, and the impedance circuit 1032I3 is connected to the pattern 1032LB via the region 1032T3. Each of the regions 1032T1 to 1032T3 is a trimming region. Each of the impedance circuit 1032I1 and the impedance circuits 1032I2 and 1032I3 has different impedance values. The impedance between the comb-like electrode fingers 1032A and 1032B can be adjusted in a plurality of stages depending on a combination of whether or not each is cut. For example, the impedance ratio of each of the impedance circuits 1032I1, 1032I2 and 1032I3 is set to 1: 2: 4, corresponding to the combination of the state of cutting or connection in each surface acoustic wave sensor 1, and the reflection of the ID reflection electrode 1032 Adjust the strength to 8 levels.

  In the case of the fourth embodiment, each unit of the detection device 2 performs the following operation. The signal control unit 22 transmits an electrical signal of the detection frequency and the identification frequency (f1) to the surface acoustic wave sensor 1 via the input / output control unit 21, and detects the intensity of the electrical signal obtained as a reflection. The determination unit 23 detects the intensity of the obtained electric signal, corresponds to the level of the intensity, refers to the identification information of the storage unit 24, and compares it with the signal intensity of the reflected wave obtained from the signal control unit 22. .

  As described above, according to the present embodiment, according to the type of inspection of the surface acoustic wave sensor 1, the impedance of the ID reflective electrode is adjusted so that the reflection intensity of the surface elastic wave becomes a plurality of different intensities. The identification information for identifying the type of inspection of each of the surface acoustic wave sensors 1 can be easily set by the reflection intensity of the identification surface acoustic wave.

As another configuration of the fourth embodiment, a configuration may be used in which the reflection intensity of the identification surface acoustic wave is temporarily converted into a bit value, and this bit value is used as identification information.
FIG. 11 is a diagram showing a bit table corresponding to the reflection intensity of the ID reflection electrode of FIG. For example, the impedance of the ID reflective electrode 1032 is controlled in eight stages by trimming, and the reflection intensity is set to eight levels of level 0 to level 7.
As shown in FIG. 11, in the bit table in the fourth embodiment, the intensity of reflection of the surface acoustic wave corresponding to the reflection intensity of the surface acoustic wave element for identification 103 is “000” when the level is 0, and the level is In the case of 1, “001” is set,..., And in the case of level 7, “111” is set, and eight types of surface acoustic wave sensors can be identified. In the description of the present embodiment, the reflection intensity is controlled in eight steps, but the number of reflection intensities corresponding to the number of surface acoustic wave sensors to be identified may be set.

Fifth Embodiment
The surface acoustic wave sensor of the fifth embodiment has the same configuration as that of FIG. 6, but as in the fourth embodiment, the ID reflective electrodes 1032 (identification frequency f1) and 1033 (identification frequency f2) are used. The reflection intensity of each is adjusted to adjust the impedance of the ID reflection electrodes 1032 and 1033, and control is performed in eight steps. That is, in the fifth embodiment, the reflection intensity of each of the ID reflective electrodes 1032 and 1033 is divided into a plurality of stages, and the presence / absence of the reflection of the surface acoustic wave at the identification frequencies f1 and f2 and the reflection intensity are identified respectively. Form the information. Therefore, 16 types of identification information can be obtained at both identification frequencies f1 and f2.

  FIG. 12 is a diagram showing a configuration example of the ID reflective electrodes 1032 and 1033. In FIG. 12, a plan view of the ID reflective electrodes 1032 and 1033 as viewed from the top of the surface acoustic wave sensor 1 is shown. The ID reflective electrode 1033 is similar to the configuration of the ID reflective electrode 1032 in FIG. The impedance circuits 1033I1, 1033I2 and 1033I3 have, for example, different impedance values. As in the fourth embodiment, in order to adjust the impedance between the comb-like electrode fingers 1033A and 1033B in eight stages by a combination of whether or not each of them is cut, each of the impedance circuits 1033I1, 1033I2 and 1033I3 The ratio of impedance is set to 1: 2: 4.

  In the fifth embodiment, the signal control unit 22 transmits electrical signals of the detection frequency and the identification frequency (f1, f2) to the surface acoustic wave sensor 1 through the input / output control unit 21 and is obtained. Whether the type of inspection of the surface acoustic wave sensor 1 matches the type of inspection of the application of the detection device 2 with reference to the identification information stored in the storage unit 24 corresponding to the signal intensity of the reflected wave Make a decision on

  As described above, according to the present embodiment, identification information for identifying the type of inspection of the surface acoustic wave sensor 1 according to the type of inspection of the surface acoustic wave sensor 1 is identified surface elasticity of a plurality of different identification frequencies. It can be easily set by the combination of the reflection intensities of the waves.

Also, as another configuration of the fifth embodiment, a configuration may be used in which the combination of the reflection intensities of the identification surface acoustic waves is temporarily converted into bit values, and the bit values are used as identification information.
FIG. 13 is a diagram showing a bit table corresponding to the arrangement of the ID reflective electrode of FIG. Since the reflection intensity of the ID reflective electrode 1032 is different for each surface acoustic wave sensor, the intensity (any one of the eight levels) of the surface acoustic wave reflected and returned from the ID reflective electrode 1032 for each surface acoustic wave sensor is It is different. The same applies to the ID reflective electrode 1033.

In FIG. 13, for example, the bit table associates the lower 3 bits (the first to third bits with the identification frequency f1) and the upper 3 bits (the fourth to sixth bits) with the identification frequency f2. Then, in the lower 3 bits and the upper 3 bits, “000” is set in the case of the lowest value (level 0), “101” in the case of level 5 and “111” in the case of the maximum (level 7).
As a result, 6-bit identification information is obtained, and 64 types of surface acoustic wave sensors can be identified. Although the reflection intensity is classified into eight levels in the description of the present embodiment, the number of classes corresponding to the number of surface acoustic wave sensors to be identified may be set.

  When the obtained reflected wave is the identification frequency set in advance, the determination unit 23 determines from the bit value corresponding to the combination of the reflection intensities of the identification surface acoustic waves of the plurality of identification frequencies in the bit table of the storage unit 24. The bit value corresponding to the combination of the reflection intensities supplied from the signal control unit 22 is read out. Then, the determination unit 23 refers to a bit value indicating the type of inspection of the surface acoustic wave sensor 1 in the storage unit 24 and determines whether the inspection of the surface elastic wave sensor 1 matches the type of inspection of the application in the detection device 2 Make a decision on

Sixth Embodiment
It is the identification using the presence or absence of reflection of the surface acoustic wave of each of the identification frequencies f1 and f2 of the third embodiment and the delay time. However, in the sixth embodiment, in addition to the delay time of the surface acoustic wave at each of the identification frequencies f1 and f2, the reflection intensity of the surface acoustic wave reflected by each of the ID reflective electrodes 1032 and 1033 is used for identification. That is, the reflection intensity of the surface acoustic wave to be reflected is divided into a plurality of stages. For example, in the present embodiment, 3-bit identification information is obtained by dividing the reflection intensity of the surface acoustic wave to be reflected into eight steps.

In the sixth embodiment, the signal control unit 22 measures the frequency, delay time and signal strength of the electrical signal corresponding to the reflected surface acoustic wave. Then, the signal control unit 22 outputs the detected frequency, delay time, and delay time to the determination unit 23. When the frequency of the obtained reflected wave is the identification frequency (f1, f2), the determination unit 23 performs surface elasticity corresponding to the combination of the delay time (t1, t2) and the signal strength (one of eight levels). The wave sensor 1 is identified.
The determination unit 23 determines whether a combination (hereinafter referred to as a combination) of the reflection intensity and the delay time of the reflection of the detected identification surface acoustic wave matches the combination of the reflection intensity and the delay time stored in the storage unit 24 referred to It judges whether or not.

  As described above, according to the present embodiment, according to the type of inspection of the surface acoustic wave sensor 1, the reflection intensity of the surface acoustic wave is made different, and the impedance of the ID reflective electrode is adjusted to control the delay time. By doing this, identification information that identifies the type of inspection of each of the surface acoustic wave sensors 1 can be easily set by the combination of the reflection intensity of the reflection of the identification surface acoustic wave and the delay time.

  In addition, as another configuration of the sixth embodiment, a configuration may be used in which a combination of the reflection intensity of reflection of the identification surface acoustic wave and the delay time is temporarily converted into a bit value, and this bit value is used as identification information. That is, when the combination of the reflection intensity and the delay time of the reflection of the detected identification surface acoustic wave is obtained, the determination unit 23 refers to the bit table stored in the storage unit 24 and detects the detected surface elasticity. The identification information corresponding to the combination of the reflection intensity of the wave reflection and the delay time may be read out. In this bit table, the combination of the reflection intensity of the reflection of the identified surface acoustic wave to be detected and the delay time is associated with the bit value corresponding to this combination.

  FIG. 14 is a diagram showing a bit table corresponding to the arrangement of the ID reflective electrode of FIG. Here, the ID reflective electrode 1032 is designed to reflect the surface acoustic wave of the identification frequency f1, and the ID reflective electrode 1033 is designed to reflect the surface elastic wave of the identification frequency f2. Further, the positions of the ID reflective electrodes 1032 and 1033 before and after the placement are arbitrarily changed. The reflection intensity of each of the ID reflective electrodes 1032 and 1033 is arbitrarily changed stepwise.

  Thereby, as shown in FIG. 14 (a), for example, from the lowest value to the highest value is divided into eight steps (0 to 7 steps) for each combination of frequency and delay time, and as described above, 3 It is used as bit identification information. In the case of the delay time t1, the bit value is set to "0", and in the case of the delay time t2, the bit value is set to "1". As shown in FIG. 14B, for example, the first to fourth bits correspond to the combination of the identification frequency f1 and the delay time t1, and the fifth to eighth bits correspond to the identification frequency f1 and the delay time t2. The ninth to twelfth bits correspond to the combination of the identification frequency f2 and the delay time t1, and the thirteenth to sixteenth bits correspond to the combination of the identification frequency f2 and the delay time t2. When the delay time is t1 at the identification frequency f1 and the signal strength is one step, the first to fourth bits become "001 (signal strength one step) 0 (delay time t1)". Thereby, the reflection intensity of each of the ID reflective electrodes 1032 and 1033 is classified into eight levels, and the delay time is t1 and t2, and the identification frequency is f1 and f2 to obtain the surface elasticity by 16 bits of identification information. The wave sensor can be identified. In the description of this embodiment, two types of elastic frequency, two types of delay time, and eight reflection intensities are classified, but the number of classifications corresponding to the number of surface acoustic wave sensors to be identified may be set. .

  If the frequency of the obtained reflected wave is the identification frequency set in advance, the determination unit 23 determines from the bit table of the storage unit 24 a bit corresponding to the combination of the reflection intensity and the delay time supplied from the signal control unit 22. Read the value. Then, the determination unit 23 refers to a bit value indicating the type of inspection of the surface acoustic wave sensor 1 in the storage unit 24 and determines whether the inspection of the surface elastic wave sensor 1 matches the type of inspection of the application in the detection device 2 Make a decision on

  According to each of the first to sixth embodiments described above, the characteristics (presence or absence of reflection, reflection intensity, delay time, etc.) of the identification surface acoustic wave reflected from the ID reflection electrode are used as identification information. Thus, the type of inspection of the surface acoustic wave sensor 1 can be easily identified, and the type of inspection of the inserted surface acoustic wave sensor 1 can be easily identified. Then, based on the identification result, it is possible to execute or stop the processing of the inspection on the surface acoustic wave sensor 1 according to the type of the inspection target with respect to the detection device 2. Thereby, when the type of inspection of the surface acoustic wave sensor 1 inserted into the detection device 2 is different from the type of inspection of the application when inserted into the measurement device, the execution of the inspection is stopped and the inspection different from the purpose It is possible to prevent the output of the result.

DESCRIPTION OF SYMBOLS 1 ... surface elastic wave sensor 1a, 2a ... terminal 2 ... detection apparatus 3 ... evaluation server 21 ... input / output control part 22 ... signal control part 23 ... determination part 24 ... storage part 101 ... substrate 101S ... surface 102 ... surface elasticity for detection Wave element 103 ... surface acoustic wave element for identification 1021, 1031 ... input / output electrode 1022 ... reflection electrode 1023 ... reaction area thin film 1032, 1033 ... ID reflection electrode 1032 T, 1032 T1, 1032 T2, 1032 T3, 1033 T, 1033 T1, 1033 T2, ... area

Claims (9)

A surface acoustic wave sensor which excites a surface acoustic wave on a substrate and measures physical properties of an object to be detected which is placed on or in contact with a detection unit on the substrate by characteristic change of the surface acoustic wave,
Aside from the detection surface acoustic wave which is a surface acoustic wave for detection, the identification surface acoustic wave is excited to identify the measurement object of the surface acoustic wave sensor, and the propagation characteristic of the surface acoustic wave is used as identification information. A surface acoustic wave sensor comprising a surface acoustic wave element for identification. The surface acoustic wave element for identification is
It has an identification reflection electrode that reflects the identification surface acoustic wave of a predetermined identification frequency,
The surface acoustic wave sensor according to claim 1, wherein the reflection characteristic from the identification reflection electrode is used as identification information of the surface acoustic wave sensor. The surface acoustic wave sensor according to claim 2, wherein a plurality of the identification reflection electrodes are disposed on the propagation path of the surface acoustic wave, and each of the identification reflection electrodes is provided for each of the identification frequencies having different frequencies. The surface acoustic wave sensor according to claim 2, wherein thinning weighting is applied to an electrode for exciting the surface acoustic wave for identification. By making the position of the identification reflection electrode on the propagation path different in the propagation direction of the surface acoustic wave in the propagation path, the delay time of the identification surface acoustic wave is controlled in a plurality of types, and The surface acoustic wave sensor according to claim 3, wherein the surface acoustic wave sensor is combined with identification information that identifies the type of inspection performed by each of the surface acoustic wave sensors. By controlling the reflection intensity of the identification reflection electrode in a plurality of steps, the signal intensity reflected by the surface acoustic wave for identification is controlled in a plurality of types, and individual surface acoustic wave sensors are performed by combination with the identification frequency The surface acoustic wave sensor according to claim 2 or 3, which is used as identification information of an inspection. The delay time of the surface acoustic wave for identification is controlled by a plurality of types by making the position of the identification reflection electrode on the propagation path of the surface acoustic wave different in the propagation direction of the surface acoustic wave for identification of the propagation path. And controlling the reflection intensity of the identification reflection electrode in a plurality of steps to control the signal intensity reflected by the surface acoustic wave for identification in a plurality of types, and the identification frequency of the surface acoustic wave element for identification and The surface acoustic wave sensor according to claim 2 or 3, wherein the surface acoustic wave sensor is combined with identification information for identifying the type of inspection performed by each of the surface acoustic wave sensors. The surface acoustic wave sensor according to claim 6 or 7, wherein the reflection intensity of the identification reflection electrode is adjusted depending on whether or not an impedance element is connected to the identification reflection electrode. A surface acoustic wave sensor according to any one of claims 1 to 8 is provided, the output signal of the surface acoustic wave sensor is compared with the identification information, and the input is made from the surface acoustic wave sensor. A measurement system comprising: a detection unit that determines whether or not the output signal matches the identification information indicating the type of inspection performed using the surface acoustic wave sensor.

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